Advanced Quantum Field Theory: Geometry of the gauge fields
This is a course on quantum field theory normally taught as a second semester of quantum field theory for physics graduate students.

讲师
日期
2024年09月12日 至 12月05日
位置
Weekday | Time | Venue | Online | ID | Password |
---|---|---|---|---|---|
周三,周四 | 13:30 - 15:05 | A3-2-301 | ZOOM 11 | 435 529 7909 | BIMSA |
修课要求
Basic knowledge of quantum fields and basic elements of perturbation theory
课程大纲
The major themes of the course are the geometry and topology of the gauge fields, quantization of non-Abelian gauge fields,
their topological and geometric effects and geometric effects and quantum anomalies (the current anomaly and the gravitational anomaly).
their topological and geometric effects and geometric effects and quantum anomalies (the current anomaly and the gravitational anomaly).
听众
Graduate
视频公开
公开
笔记公开
公开
语言
英文
讲师介绍
Pavel Wiegmann received his PhD and Habilitation from the Landau Institute of Theoretical Physics in Moscow, where he worked as a Senior Researcher until 1994. Between 1990 and 1992, he held a similar position at Princeton University and the Institute for Advanced Study before joining the faculty at the University of Chicago, where he currently holds the title of Distinguished Service Professor at the Kadanoff Center for Theoretical Physics.
In 2004, he was an invited speaker at the International Congress of Mathematicians in Madrid. He received the Humboldt Prize (also known as the Humboldt Research Award) in 2002 and became a Fellow of the American Physical Society in 2003. That same year, he held the Kramers Chair at the Spinoza Institute in Utrecht, Netherlands, and in 2006, he held the Chaire Internationale Blaise Pascal in Île-de-France. He was named a Simons Foundation Fellow in 2015 and received the Onsager Prize from the American Physical Society in 2017.
Wiegmann's research interests span a wide range of topics, including: Theoretical Condensed Matter Physics (electronic physics in low dimensions, quantum magnetism, correlated electronic systems, quantum Hall effects, topological aspects of condensed matter, quantum field theories, and quantum liquids);Mathematical Physics (integrable models of quantum field theory and statistical mechanics, quantum groups, and representation theory);Quantum Field Theory (anomalies, conformal field theory, quantum gravity, stochastic geometry, and random matrix theory); Nonlinear Physics (stochastic aspects of pattern formation, interface dynamics, incommensurate systems, integrable aspects of nonlinear physics, and singularities in hydrodynamics and fluid mechanics).